细胞DNA损伤检控系统在维持端粒稳定中的功能

真核生物的DNA损伤检控系统是维持细胞基因组稳定的一个重要机制,该系统能检测细胞在生命活动过程中出现的DNA损伤并引发细胞周期阻滞,对DNA损伤进行修复,以维持细胞遗传的稳定性。端粒是位于真核细胞染色体末端由重复DNA序列和蛋白质组成的复合物,具有保护染色体、介导染色体复制、引导减数分裂时的同源染色体配对和调节细胞衰老等作用。虽然端粒与DNA双链断裂都具有作为线性染色体末端的共同特点,但正常端粒并不像DNA双链断裂那样激活DNA损伤检控系统。另一方面,端粒又与DNA损伤相似,因为多种DNA损伤检控蛋白在端粒长度稳定中起重要作用。因此DNA损伤检控系统既参与了维持正常端粒的完整性,又可对端粒损伤作出应答。现就DNA损伤检控系统在维持端粒稳定中的作用及其对功能缺陷端粒的应答作一简要综述。     

基因组编辑对酿酒酵母DNA的损伤作用及修复响应

【目的】为了研究基因组编辑工具CRISPR/Cas9和CRISPR/Cpf1所产生的DNA双链断裂(DNA doublestrandbreak,DSB)对酿酒酵母DNA的损伤作用及修复响应情况,对比化学物质甲基磺酸甲酯(methyl methanesulfonate,MMS)对酿酒酵母基因组DNA的损伤和修复,阐明编辑细胞在细胞水平和转录水平上的变化。【方法】起始细胞分为两种情况,包括未进行细胞周期同步化和被α-因子同步化细胞周期至G0/G1期。检测CRISPR/Cas9和CRISPR/Cpf1处理后编辑细胞的生长情况。利用流式细胞术检测编辑细胞的细胞周期延滞的情况。利用荧光定量PCR检测编辑细胞和MMS处理细胞后DNA损伤响应关键基因转录表达水平的变化情况。【结果】起始细胞无论是未同步化还是同步化,其生长均受到基因组编辑抑制,细胞存活率降低,细胞周期被滞留在G2/M期,而MMS处理导致细胞周期S期的滞留。此外,随编辑时间的延长,突变率增加,细胞存活率降低。CRISPR/Cpf1编辑细胞的突变率和存活率均低于CRISPR/Cas9,由此可见,CRISPR/Cpf1对细胞的损伤强度高于CRISPR/Cas9。两种编辑均诱导酵母DNA损伤响应关键基因RNR3及HUG1转录水平显著上调,并且CRISPR/Cpf1介导的上调幅度大于CRISPR/Cas9,但两者均低于MMS的处理。【结论】本研究解析了CRISPR/Cas9和CRISPR/Cpf1介导的基因组编辑在细胞水平和转录水平上对DNA损伤作用及修复响应,初步揭示了酿酒酵母应对不同类型的DSB损伤时响应程度的差异,为提高基因组编辑工具的编辑能力和评估基因编辑安全性提供了重要依据。     

CpG ODNs对肿瘤细胞端粒酶活性及细胞周期和凋亡的影响

应用TRAP PCR ELISA法检测CpGODNs及E .coliDNA对肿瘤细胞端粒酶活性的影响变化 ,同时用流式细胞仪检测细胞周期的变化及凋亡的产生 ,从基因水平探讨其抗肿瘤机制。实验发现活性形式的CpGODNs可显著降低肿瘤细胞端粒酶活性 ,E .coliDNA的下调作用出现在 48h之后 ,二者均可使G0 /G1期细胞含量增加 ,但均未引起凋亡。结果表明 ,CpGODNs及E .coliDNA在基因水平可通过抑制端粒酶活性达到抗肿瘤目的 ,但不能诱导肿瘤细胞凋亡。     

人细胞端粒DNA复制与长度维持

端粒位于染色体末端,由短的串联重复DNA片段及其结合蛋白组成。端粒在维持基因组稳定性及染色体结构完整性方面发挥着重要作用。端粒DNA由富含G/C的序列构成,包括双链区及G含量高的3'悬垂单链区(G-overhang,G-tail)。端粒DNA能够形成G四联体(G-quadruplex)和T环(T-loop)等高级结构。许多与DNA损伤修复相关的蛋白质参与端粒DNA的复制与端粒结构的维持,并相对于基因组的其他区域,端粒的DNA复制较为特别,从广义上讲,端粒DNA的复制可以包括双链复制(telomere replication),端粒酶复制延伸(telomerase extension)和C链补齐(C-rich fill-in)。端粒双链复制引起的端粒长度缩短是导致人体细胞衰老的重要原因,而端粒酶复制延伸及C链补齐是干细胞及肿瘤细胞维持其端粒长度及持续分裂能力的主要途径。端粒复制及其结构功能研究是生物医学领域的一个重要热点,阐释端粒复制的机理将为疾病预防及治疗等提供新的思路。     

DNA氧化性损伤与端粒缩短

末端复制问题（the end replication problem）不能完全解释端粒在某些细胞分裂过程中迅速缩短的现象.40％的高压氧下细胞传代次数降低,端粒缩短速率增大,细胞出现衰老特征,端粒DNA上单链断裂积累.推测端粒缩短的主要原因在于衰老过程中或氧胁迫下端粒DNA单链断裂增多,使端粒末端单链片段在DNA复制时丢失.端粒酶和活性氧对端粒长度的正负调控作用的准确机制还有待于更深入的研究.     

端粒及端粒酶活性的调控机制

广义的端粒由帽子、双链的串联重复序列的DNA核心部分及亚端粒构成,其结合蛋白是一个复合体,由TRF1、TRF2、TIN2、Pot1、TPP1、RAP1 6个亚单位组成;另外,还结合组蛋白的特定成分H3K9三甲基聚合体和H4K20三甲基聚合体。端粒酶主要由hTerc、hTert、dyskerin构成。端粒的功能主要受端粒酶的活性调控;而端粒酶活性主要受hTert及hTerc的转录水平和转录后的剪切、hTert的翻译等因素的调控。端粒与端粒酶结构和功能的异常与细胞衰老及肿瘤的发生、发展关系密切。     

重离子辐照酿酒酵母DNA损伤修复途径研究进展

重离子辐照通过直接和间接作用导致生物体DNA产生损伤,包括DNA的链断裂、碱基的插入或丢失以及氧化损伤等.DNA损伤直接影响复制、转录和蛋白质合成,同时还是突变的重要原因,因此,DNA损伤修复系统尤为重要.在酿酒酵母中,这些损伤主要是通过同源重组修复(homologous recombination repair,HRR)、碱基错配修复(mismatch repair,MMR)和碱基切除修复(base excision repair,BER)等途径来修复的.作为真核生物研究的模式生物,对于酿酒酵母DNA损伤修复的HRR、MMR和BER途径研究颇多,也不断有一些新的成果出现,特别是对于相关途径的完善和相关蛋白的深化更是研究热点,在此对近年来有关重离子辐照酿酒酵母DNA损伤修复途径方面的研究做一综述.     

NBS1在DNA断裂损伤反应和维持端粒稳定中的作用

NBS1作为MRE11/RAD50/NBS1复合物的组分之一,是细胞应答DNA损伤的一个关键蛋白质,在DNA双链断裂修复和维持基因组稳定中发挥重要的作用。端粒是染色体末端由DNA重复序列和蛋白质构成的复合体,其独特结构与DNA双链断裂非常相似。最近几年的研究发现NBS1与端粒也有着十分密切的联系。综述了NBS1在DNA损伤反应中的作用,并探讨NBS1参与维持端粒稳定中的分子机制。     

铅和硒对端粒长度、端粒酶及端粒结合蛋白的影响

以酿酒酵母细胞为实验材料 ,在分子水平上研究铅 (Pb)和硒 (Se)对端粒长度、端粒酶及端粒结合蛋白的影响。结果发现 :与对照组相比 ,添加 1mg/LPb的培养基中培养 10 0代后的酿酒酵母细胞中端粒DNA的平均长度缩短 ,端粒结合蛋白Rap1p含量减少 ,而且Rap1p蛋白的二级结构受到扰动、端粒酶活性降低、43%的细胞死亡。加 1mg/LSe培养 10 0代后的酿酒酵母细胞与对照组相比 ,细胞中端粒平均长度增加 ,Rap1p蛋白浓度和二级结构保持稳定 ,端粒酶活性增加 ,细胞正常存活。以上结果表明 ,Pb对酿酒酵母细胞端粒有损伤 ,而且其损伤在子代细胞中有累积效应 ;而Se对Pb损伤具有一定程度的修复保护作用 ,适量给机体补Se对抑制细胞损伤和衰老有一定作用。由于端粒的特殊结构特征 ,推断Pb和Se是通过作用于端粒酶及端粒结合蛋白而间接影响端粒长度的     

溴氰菊酯致大鼠DNA损伤及对肝功能的影响

目的：研究溴氰菊酯（DM）对大鼠外周血淋巴细胞DNA的损伤作用及对肝脏功能的影响。方法：32只雌性Wistar大鼠随机分成4组,染毒剂量分别为0,3．125,6．250,12．500mg／kg,连续灌胃染毒10天。DNA损伤采用单细胞凝胶电泳（彗星实验）进行评价,并测定丙氨酸氨基转移酶（ALT）以反映肝功能变化。结果：染毒组大鼠外周淋巴细胞的尾DNA％（Tail DNA％）、尾矩（Tail Moment）和Olive尾矩（Olive Tail Moment）均高于对照组（P〈0．05）,差别有统计学意义。各染毒组与对照组的肝功能差异均无统计学意义。结论：DM可导致外周血淋巴细胞DNA损伤。     

Comparative genotyping of the Saccharomyces cerevisiae laboratory strains S288C and CEN.PK113-7D using oligonucleotide microarrays

To analyse the reliability and accuracy of genotype analysis with high-density oligonucleotide microarrays, this method and other experimental approaches were used to analyse genomic DNA of two popular Saccharomyces cerevisiae laboratory strains. S288C was used for systematic sequencing of 'the' S. cerevisiae genome; CEN.PK113-7D is a popular strain for physiological studies and functional genomics. Random amplified polymorphic DNA, electrophoretic karyotyping and microarray analysis all indicated a high level of sequence similarity between the two strains. In the microarray analysis, as few as 288 (4.5%) of the ca. 6300 represented yeast genes were identified that yielded significantly different hybridisation intensities between the two strains. These could be classified as amplified, absent, or with sequence polymorphism in CEN.PK113-7D compared to S288C. A detailed analysis focused on the subset of 25 genes called absent in CEN.PK113-7D. Among these absent genes, 17 were clustered together on five chromosomes, mainly in subtelomeric regions. Thorough analysis of these regions by polymerase chain reaction (PCR) and restriction fragment length polymorphism confirmed the absence of these genes in CEN.PK113-7D. Surprisingly, three of these regions were not smaller in CEN.PK113-7D chromosomes, indicating that they may harbour unidentified and potentially new sequences. In addition, eight genes called absent by the microarrays were scattered over the chromosomes. Using diagnostic PCR most of these genes were actually found to be present in CEN.PK113-7D, but after sequencing were found to differ significantly at the DNA level from S288C, explaining the poor hybridisation to the arrays. Our results indicate that DNA microarrays are a powerful tool for determining genotypic similarity between different yeast strains. However, to obtain meaningful information at the individual gene level, this method should be backed up by additional techniques.     

Comprehensive understanding of Saccharomyces cerevisiae phenotypes with whole-cell model WM_S288C

Biological network construction for Saccharomyces cerevisiae is a widely used approach for simulating phenotypes and designing cell factories. However, due to a complicated regulatory mechanism governing the translation of genotype to phenotype, precise prediction of phenotypes remains challenging. Here, we present WM_S288C, a computational whole-cell model that includes 15 cellular states and 26 cellular processes and which enables integrated analyses of physiological functions of Saccharomyces cerevisiae. Using WM_S288C to predict phenotypes of S. cerevisiae, the functions of 1140 essential genes were characterized and linked to phenotypes at five levels. During the cell cycle, the dynamic allocation of intracellular molecules could be tracked in real-time to simulate cell activities. Additionally, one-third of non-essential genes were identified to affect cell growth via regulating nucleotide concentrations. These results demonstrated the value of WM_S288C as a tool for understanding and investigating the phenotypes of S. cerevisiae.     

A new transformation system of Saccharomyces cerevisiae with blasticidin S deaminase gene

A new method for transformation of Saccharomyces cerevisiae that allows selection was developed. As the frequency of spontaneous blasticidin S resistant mutants from diploid type yeast strain (X-2180AB) was 5.2×10^–6, which was a thousandfold less than that from haploid type yeast strain (X-2180B), it was considered that the mechanism of spontaneous blasticidin S resistant mutations was related to recessive gene. Industrial yeasts, which were diploid, were transformed with blasticidin S deaminase gene from Aspergillus terreus to blasticidin S resistance. Expression of blasticidin S deaminase gene allowed selection of transformants from industrial yeasts.     

MUS81 encodes a novel helix-hairpin-helix protein involved in the response to UV- and methylation-induced DNA damage in Saccharomyces cerevisiae

The gene MUS81 (Methyl methansulfonate, UV sensitive) was identified as clone 81 in a two-hybrid screen using the Saccharomyces cerevisiae Rad54 protein as a bait. It encodes a novel protein with a predicted molecular mass of 72,316 (632 amino acids) and contains two helix-hairpin-helix motifs, which are found in many proteins involved in DNA metabolism in bacteria, yeast, and mammals. Mus81p also shares homology with motifs found in the XPF endonuclease superfamily. Deletion of MUS81 caused a recessive methyl methansulfonate- and UV-sensitive phenotype. However, mus81Δ cells were not significantly more sensitive than wild-type to γ-radiation or double-strand breaks induced by HO endonuclease. Double mutant analysis suggests that Rad54p and Mus81p act in one pathway for the repair of, or tolerance to, UV-induced DNA damage. A complex containing Mus81p and Rad54p was identified in immunoprecipitation experiments. Deletion of MUS81 virtually eliminated sporulation in one strain background and reduced sporulation and spore viability in another. Potential homologs of Mus81p have been identified in Schizosaccharomyces pombe, Caenorhabditis elegans and Arabidopsis thaliana. We hypothesize that Mus81p plays a role in the recognition and/or processing of certain types of DNA damage (caused by UV and MMS) during repair or tolerance processes involving the recombinational repair pathway. Received: 9 December 1999 / Accepted: 24 February 2000     

Characterization of gamma-glutamylamidase-glutaminase activity in Saccharomyces cerevisiae

In a foregoing paper we have shown the presence in the yeast Saccharomyces cerevisiae of an enzyme catalyzing the hydrolysis of L-gamma-glutamyl-p-nitroanilide, but apparently distinct from gamma-glutamyltranspeptidase. The cellular level of this enzyme was not regulated by the nature of the nitrogen source supplied to the yeast cell. Purification was attempted, using ion exchange chromatography on DEAE Sephadex A 50, salt precipitations and successive chromatographies on DEAE Sephadex 6B and Sephadex G 100. The apparent molecular weight of the purified enzyme was 14,800 as determined by gel filtration. As shown by kinetic studies and thin layer chromatography, the enzyme preparation exhibited only hydrolytic activity against gamma-glutamylarylamide and L-glutamine with an optimal pH of about seven. Various gamma-glutamylaminoacids, amides, dipeptides and glutathione were inactive as substrates and no transferase activity was detected. The yeast gamma-glutamylarylamidase was activated by SH protective agents, dithiothreitol and reduced glutathione. Oxidized glutathione, ophtalmic acid and various gamma-glutamylaminoacids inhibited competitively the enzyme. The activity was also inhibited by L-gamma-glutamyl-o-(carboxy)phenylhydrazide and the couple serine-borate, both transition-state analogs of gamma-glutamyltranspeptidase. Diazooxonorleucine, reactive analog of glutamine, inactivated the enzyme. The physiological role of yeast gamma-glutamylarylamidase-glutaminase is still undefined but is most probably unrelated to the bulk assimilation of glutamine by yeast cells.     

Repair of Oxidative DNA Damage in Saccharomyces cerevisiae

Malfunction of enzymes that detoxify reactive oxygen species leads to oxidative attack on biomolecules including DNA and consequently activates various DNA repair pathways. The nature of DNA damage and the cell cycle stage at which DNA damage occurs determine the appropriate repair pathway to rectify the damage. Oxidized DNA bases are primarily repaired by base excision repair and nucleotide incision repair. Nucleotide excision repair acts on lesions that distort DNA helix, mismatch repair on mispaired bases, and homologous recombination and non-homologous end joining on double stranded breaks. Post-replication repair that overcomes replication blocks caused by DNA damage also plays a crucial role in protecting the cell from the deleterious effects of oxidative DNA damage. Mitochondrial DNA is also prone to oxidative damage and is efficiently repaired by the cellular DNA repair machinery. In this review, we discuss the DNA repair pathways in relation to the nature of oxidative DNA damage in Saccharomyces cerevisiae.     

Biosynthesis of L-ascorbic acid (vitamin C) by Saccharomyces cerevisiae

Saccharomyces cerevisiae cells incubated with D-glucose (D-Glc), D-galactose or D-mannose (D-Man) synthesised D-erythroascorbic acid (D-EAA) but not L-ascorbic acid (L-AA). Accumulation of D-EAA was observed in cells incubated with D-arabinose (D-Ara) whilst accumulation of L-AA occurred in cells incubated with L-galactose (L-Gal), L-galactono-1,4-lactone and L-gulono-1,4-lactone. When S. cerevisiae cells were incubated with D-[U-(14)C]Glc, D-[U-(14)C]Man or L-[1-(14)C]Gal, incorporation of radioactivity into L-AA was observed only with L-[1-(14)C]Gal. Pre-incubation of yeast cells with D-Ara substantially reduced the incorporation of L-[1-(14)C]Gal into L-AA. Our results indicate that, under appropriate conditions, yeast cells can synthesise L-AA via the pathway naturally used for D-EAA biosynthesis.     

酿酒酵母DNA复制的精确时空控制

DNA复制是最基本的生命活动之一。DNA复制本身的错误及其过程控制的异常是细胞内基因组不稳定的主要来源,会导致细胞生长异常、衰老、癌变乃至死亡。为了保证基因组DNA能够精确且完整的复制,DNA复制受到严格的调控。在G1期,DNA复制解旋酶的核心组分Mcm2-7复合体被招募到复制起点,获得复制许可资格。进入S期后,在两个周期性蛋白激酶及多个支架蛋白的作用下,复制解旋酶的激活因子Cdc45和GINS复合体被招募至Mcm2-7,形成解旋酶全酶Cdc45-Mcm2-7-GINS (CMG)复合体。随后,众多复制相关蛋白在精准的时空控制下被招募至CMG平台并组装成复制机器,起始DNA双向复制。当相向而行的两个复制叉相遇,复制机器会从DNA链上解离下来,从而完成DNA复制。关于DNA复制过程的研究在近十年来取得了跨越式的突破。本文以酿酒酵母为例,围绕所有真核生物中都高度保守的DNA复制控制开关——CMG解旋酶,对真核生物DNA复制的最新进展进行综述。     

Production of Extracellular lipases by Saccharomyces cerevisiae

Seven strains of Saccharomyces cerevisiae all produced lipase when grown in shake flask culture. The best strain, DSM 1848, produced 4.0U of lipase in the medium containing olive oil and yeast extract. Production of the lipase was growth-associated.